An electric parking brake system according to one embodiment comprises: a first electric parking brake provided at a front wheel of a vehicle so as to generate a first clamping force; a second electric parking brake provided at a rear wheel of the vehicle so as to generate a second clamping force; an inclination sensor for detecting the inclination degree of the vehicle; and a control unit for determining the total clamping force required for parking on the basis of the inclination degree of the vehicle and vehicle weight information, determining the electric parking brake, to be operated, from among the electric parking brakes according to the determined total clamping force, and operating the determined electric parking brake.

A controller is provided to, in response to a speed of the vehicle exceeding an allowable speed based on a measured grade while the vehicle is running and in neutral or park, actuating a vehicle holding mechanism to stop the vehicle.

A brake control system for a motor vehicle having a plurality of wheels, brakes for applying a braking effort to one or more of the wheels, and a movement sensor for detecting movement of the vehicle. The system comprises a brake actuator for actuating the brakes to supply a braking effort and a brake controller for controlling the brake actuator. The brake controller is configured to determine an acceleration of the vehicle based on movement detected by the movement sensor and to ensure that the brake actuator supplies a braking effort if the determined acceleration exceeds a set acceleration limit.

A system for controlling a trailer brake output circuit includes an input device outputting a signal in response to receiving an input from a user, and an electronic control unit. The electronic control unit includes one or more processors, one or more memory modules, the trailer brake output circuit outputting a trailer brake output signal, and machine readable instructions. The electronic control unit receives the signal from the input device, limits the trailer brake output signal to a first value when the trailer brake output circuit outputs the trailer brake output signal in response to the signal received from the input device, and limits the trailer brake output signal to a second value when the trailer brake output circuit outputs the trailer brake output signal not in response to the signal received from the input device. The second value is smaller than the first value.

A protection device for a drivetrain of a motor vehicle having an engine and an automatic transmission, with at least one hydraulic converter. In order to protect the drivetrain, the protection device has a sensor device and a control device. The sensor device is designed to detect a rolling movement of the motor vehicle counter to the selected direction of travel of an engaged gearspeed of the automatic transmission, and the control device is designed to control a brake system of the motor vehicle as a function of the detected rolling movement, in order to limit a rolling speed of the motor vehicle counter to the selected direction of travel to a maximum speed.

A system for controlling a trailer brake output circuit includes an input device outputting a signal in response to receiving an input from a user, and an electronic control unit. The electronic control unit includes one or more processors, one or more memory modules, the trailer brake output circuit outputting a trailer brake output signal, and machine readable instructions. The electronic control unit receives the signal from the input device, limits the trailer brake output signal to a first value when the trailer brake output circuit outputs the trailer brake output signal in response to the signal received from the input device, and limits the trailer brake output signal to a second value when the trailer brake output circuit outputs the trailer brake output signal not in response to the signal received from the input device. The second value is smaller than the first value.

A vehicle stability control device includes a yaw moment generation device and a control device. A variation yaw moment generated by simultaneous turn and acceleration/deceleration is expressed as a function of a longitudinal acceleration and a lateral acceleration. A longitudinal force and a lateral force of a tire have non-linear load dependency. The variation yaw moment when assuming that the load dependency is linear is a first variation yaw moment. The variation yaw moment considering the non-linear load dependency is a second variation yaw moment that is expressed as a product of the first variation yaw moment and a correction gain. In vehicle stability control, the control device controls the yaw moment generation device to generate a counter yaw moment counteracting the second variation yaw moment, based on the longitudinal acceleration, the lateral acceleration, and the correction gain.

A method for controlling braking of a vehicle is configured to prevent a jerk which occurs when a driver removes his or her foot from a brake pedal when the vehicle is parked or stopped using a parking gear. The method is carried out such that a constant braking force is transferred to front and rear wheels, and braking pressure is gradually removed by using Electronic Stability Control (ESC) in consideration of a longitudinal direction acceleration in a state where the vehicle is parked or stopped.

A method is disclosed for the operation of an automated parking brake of a motor vehicle with a hydraulic operating brake and an automated parking brake. The parking brake can adopt at least a disengaged position, an engaged position, and an intermediate position between the disengaged position and the engaged position. The method includes determining a parking variable representing a parking process of the motor vehicle, and bringing the parking brake into the intermediate position in response to the determined parking variable.

A method for mitigating sway of a trailer being towed by a leading vehicle is disclosed. The method may involve using a controller of the vehicle to determine when a trailer sway condition has arisen that requires a mitigating action. The controller may be used to actuate a plurality of brakes of the vehicle, or to increase braking pressure being applied by a driver of the vehicle, when the trailer is detected as swaying toward a centerline of the vehicle from one side or another of the vehicle centerline. The controller may further be used to release the plurality of brakes, or to decrease a braking pressure being commanded by the driver, before the trailer has swayed past the vehicle centerline, and to repeatedly apply and release the vehicle brakes only while the trailer is detected as swaying toward the vehicle centerline, until the trailer sway condition has been mitigated.